Reversible release of chick embryo fibroblast cultures from density dependent inhibition of growth

Initiation of proliferation in density-inhibited chick embryo fibroblast cultures induced by insulin or trypsin was partially reversed by replacing the medium with supernatants from parallel non-stimulated cultures. Growth stimulation by neuraminidase, pokeweed mitogen, bacterial lipo polysaccharide or purified tuberculin was less, or not at all, affected by this procedure. Medium change per se caused some proliferation in non-stimulated cultures. Increased rate of sugar uptake in insulin-stimulated cultures returned to the level of that in non-stimulated cultures within a few hours after medium change. This reversion took place apparently irrespective of the phase of the cell cycle. Replacing the medium with supernatants from non-stimulated cultures induced a rapid decline in subsequent thymidine incorporation during the first S-phase, and completely abolished the second peak of DNA synthesis. The fraction of cells irreversibly committed to mitosis increased when the time after stimulation increased. Less than three hours' incubation with insulin or trypsin was needed to initiate proliferation of a significant fraction of the cell population. It is concluded that reversion of the initiated cycle of a given cell is no more possible after the cell has entered the S-phase.     

Reversible release of chick embryo fibroblast cultures from density dependent inhibition of growth.

Initiation of proliferation in density-inhibited chick embryo fibroblast cultures induced by insulin or trypsin was partially reversed by replacing the medium with supernatants from parallel non-stimulated cultures. Growth stimulation by neuraminidase, pokeweed mitogen, bacterial lipopolysaccharides or purified tuberculin was less, or not at all, affected by this procedure. Medium change per se caused some proliferation in non-stimulated cultures. Increased rate of sugar uptake in insulin-stimulated cultures returned to the level of that in non-stimulated cultures within a few hours after medium change. This reversion took place apparently irrespective of the phase of the cell cycle. Replacing the medium with supernatant from non-stimulated cultures induced a rapid decline in subsequent thymidine incorporation during the first S-phase, and completely abolished the second peak of DNA synthesis. The fraction of cells irreversibly committed to mitosis increased when the time after stimulation increased. Less than three hours' incubation with insulin or trypsin was needed to initiate proliferation of a significant fraction of the cell population. It is concluded that reversion of the initiated cycle of a given cell is no more possible after the cell has entered the S-phase.     

Serum-stimulated phosphate uptake and initiation of fibroblast proliferation

Previous studies have shown that initiation of proliferation of density-inhibited fibroblasts by fresh serum is accompanied by a rapid increase in phosphate uptake. This increase might be a key event in the initiation of DNA synthesis. The present studies examined this possibility. Mouse 3T3, secondary chick embryo, or human diploid foreskin cultures were grown to quiescence in medium containing varying levels of serum. When proliferation of the cultures was initiated by addition of fresh serum, the changes in phosphate uptake were inversely related to the final increases in cell number. Additional experiments showed that the change in phosphate uptake following serum addition was determined by the level of phosphate uptake prior to serum addition. Addition of dexamethasone to quiescent 3T3 cultures caused them to proliferate but did not increase phosphate uptake. Similarly, trypsin or insulin stimulated proliferation of quiescent secondary chick embryo cultures, but caused little or no change in phosphate uptake. Quiescent 3T3 cultures switched to medium containing fresh serum and reduced levels of phosphate showed a decrease in both phosphate uptake and intracellular phosphate pool size. Cell proliferation in these cultures, however, was stimulated to the same degree as cultures switched to medium containing fresh serum and the normal amount of phosphate. In addition, quiescent secondary chick embryo cultures switched to medium containing fresh serum and no phosphate showed a decrease in the intracellular phosphate pool size. Thymidine incorporation and final cell number in these cultures, however, was stimulated to the same or higher degree than in cultures switched to medium containing fresh serum and the normal amount of phosphate. These results demonstrate that the rapid increase in phosphate uptake following addition of fresh serum to quiescent fibroblasts is not a necessary event for the initiation of proliferation.     

Uridine transport and RNA synthesis in growing and in density-inhibited animal cells

Both chick embryo fibroblasts and mouse 3T3 cells reduce the rate at which they incorporate H³ uridine into RNA as their growth becomes inhibited at high cell density. This reduction occurs as a function of the cell population density, and with chick embryo cells (in contrast to 3T3 cells) it is not accompanied by significant medium alterations. This indicates the importance of the cell population density in the control of cellular metabolism. The decline in H³ uridine incorporation is paralleled by a decline in the rate of uptake of the isotope into the acid-soluble pool, suggesting that decreased entry of H³ uridine into the cell, rather than a decreased rate of RNA synthesis, is responsible for the reduced rate of incorporation into RNA of density-inhibited cells. This suggestion was confirmed by finding that when the restriction on uridine uptake was overcome by increasing the concentration of uridine in the medium, the density-dependent inhibition of uridine incorporation was largely reversed. We conclude that, even though the rate of H³ uridine incorporation into RNA is reduced three- to five-fold in density-inhibited cells, the rate of synthesis of pulse-labeled RNA continues at 70 to 85% of the rapidly-growing rate.     

Hexose uptake and control of fibroblast proliferation

The role of glucose uptake in control of cell growth was studied by experimentally varying the rate of glucose uptake and examining the subsequent effect on initiation and cessation of cell proliferation. The rate of glucose uptake was varied by adjusting the concentration of glucose in the culture medium. This permitted analysis of two changes in rate of glucose uptake which are closely related to the regulation of cell growth: (1) the rapid increase in glucose uptake that can be detected within several minutes after mitogenic stimulation of quiescent fibroblasts and (2) the decrease in glucose uptake which accompanies growth to a quiescent state. Quiescent cultures of mouse 3T3, human diploid foreskin and secondary chick embryo cells were switched to fresh serum-containing medium with either the normal amount of glucose or a reduced level that lowered the rate of glucose uptake below the rate characteristic of quiescent control cells. The subsequent increases in cell number were equal in both media, demonstrating that the increase in glucose uptake, commonly observed after mitogenic stimulation, was not necessary for initiation of cell division. Measurements of intracellular D-glucose pools after serum stimulation of quiescent cells revealed that the increase in glucose uptake was not accompanied by a detectable change in the intracellular concentration of glucose. Nonconfluent growing cultures of mouse 3T3, human diploid foreskin and secondary chick embryo cells were switched to low glucose media, lowering the rate of glucose uptake below levels observed for quiescent cells. This did not affect rates of DNA synthesis or cell division over a several-day period. Thus, the decrease in glucose uptake, which usually occurs at about the same time as the decrease in DNA synthesis as cells grow to quiescence, does not cause the decline in cell proliferation. Experiments indicated that there was no set temporal relationship between the decline in glucose uptake and DNA synthesis as cells grew to quiescence. The sequence was variable and probably depended on the cell type as well as culture conditions. Measurements of intracellular D-glucose pools in secondary chick embryo cells demonstrated that the internal concentration of glucose in these cells did not significantly vary during growth to quiescence. Taken together, our results show that these fluctuations in the rate of glucose uptake do not lead to detectable changes in the intracellular concentration of glucose and that they do not control cell proliferation rates under usual culture conditions.     

Antagonistic effects of insulin and cortisol on coordinate control of metabolism and growth in cultured fibroblasts

A variety of metabolic and biosynthetic pathways in chick embryo fibroblasts are stimulated coordinately by many unrelated exogenous agents. Three of the best characterized components of this coordinate response are the uptake of 2-deoxy-D-glucose (2-dGlc) and of uridine and the incorporation of thymidine into DNA. Insulin stimulates and cortisol inhibits the coordinate response. In cortisol-treated cultures, as little as 10^?3 units/ml of insulin may stimulate thymidine incorporation 4-fold and 10^?1 units/ml may stimulate as much as 40-fold. The higher concentrations of insulin completely override the inhibitory effect of cortisol. They also cause about a 5-fold stimulation of the uptake of 2-dGlc and of uridine and a 2-fold stimulation of proline incorporation into protein. The uptake rates of 2-dGlc and uridine double within 30 minutes after addition of insulin to cortisol-inhibited cultures, but the incorporation of thymidine only begins to increase markedly after a 4-hour delay. When cortisol is added to cultures in the absence of insulin, the rates of uptake of 2-dGlc and uridine begin to decrease within two hours, but the incorporation of thymidine remains constant for two hours before beginning to decrease. Deprivation of Mg²⁺ inhibits the accelerated coordinate response maintained by insulin, but does not further the inhibition induced by cortisol. Results with metabolic inhibitors indicate that the stimulation of 2-dGlc and uridine uptake by insulin do not require RNA synthesis, and also suggest that they do not require protein synthesis. These and other findings can be explained by a model for coordinate control in which insulin increases and cortisol decreases the availability of Mg²⁺ for a wide spectrum of regulatory reactions in different metabolic pathways. In this model both hormones affect only the rates of ongoing reactions and do not instruct the cell to carry out specific new reactions unless the cell was predetermined to do so.     

Deoxyglucose transport of uninfected, murine sarcoma virus-transformed, and murine leukemia virus-infected mouse cells

The initial rates of deoxy-D-glucose transport by cultures of growing and density-inhibited mouse embryo cells and lines of mouse cells transformed spontaneously or after infection by murine leukemia virus or murine sarcoma virus were investigated as a function of the deoxyglucose concentration. The apparent K_m for deoxyglucose transport was about the same for all types of cells (1–2 mM). The V_max of secondary cultures of mouse embryo cells decreased from 6 nmoles/10⁶ cells/minute for sparse cultures to less than 1 nmole/10⁶ cells/minute for density-inhibited cultures. The V_max was about the same whether estimated in monolayer culture or in suspensions of cells dispersed by treatment with trypsin. The V_max for deoxyglucose transport by the established cells, whether transformed spontaneously or by virus infection, was 4 to 25 times higher than that for density-inhibited mouse embryo cells and was independent of the cell density of the cultures. Deoxyglucose transport was competitively inhibited by Cytochalasin B, Persantin, glucose and 3-O-methyl-D-glucose and the apparent K_i values of inhibition were similar for the mouse embryo cells and the various cell lines. Similarly, the sensitivity of the glucose transport systems to inactivation by p-chloromercuribenzoate was about the same for all types of cells. The results suggest that the glucose transport system of the normal mouse embryo cells and the cells of the various established lines is qualitatively the same, but that the number of functional transport sites differs for the various cell lines and decreases markedly in mouse embryo cells with an increase in cell density of the cultures.     

“Carrier activation” and glucose transport in Chinese hamster fibroblasts

Incubation of chinese hamster fibroblasts in glucose free medium, resulted in a 4 to 8 fold increase in the rate of D-glucose uptake and in a 3 to 4 fold increase in the uptake rate of glucose analogs (D-glucosamine, 2-Deoxy-D-glucose, 3-O-Methylglucose). In contrast to what is known for chick embryo fibroblasts, this increased hexose uptake activity is not blocked by cycloheximide in chinese hamster cells. The stimulation of synthesis of the Glucose Regulated Protein, GRP 95 which preceeds by 4 hours the stimulation of GRP 75 cannot account for the increase in hexose uptake-activity. Kinetic data have shown that the activation of glucose uptake activity following sugar starvation resulted only in a V_max increase; K_m for glucose remained constant at 0.6–0.7 mM. However, only the “activated” form of glucose uptake (glucose starvation) was very sensitive to N-ethylmaleimide. A mechanism of hexose “carrier activation” by glucose or a close metabolite is discussed.     

Modulation by the src oncogene of the effect of inhibitory diffusible factor IDF45

Density-dependent inhibition of growth has been assumed to be under the control of inhibitory molecules diffusing from dense cell cultures. Growth inhibitory factors have been fractionated or purified from medium conditioned by different cell types. In the present work, it was shown that IDF45 (inhibitory factor diffusing from 3T3 cells) decreased DNA synthesis in chick embryo fibroblasts (CEF) and was an inhibitor of CEF growth; this inhibition was reversible. Since similitudes between oncogene products and growth factors have been observed, it was of interest to compare the inhibitory effect of IDF45 upon the stimulation of DNA synthesis induced either by serum or by pp60-src. CEF infected by Ny68 virus (a mutant of Rous sarcoma virus ts for the expression of transformation) were density-inhibited at 41 degrees C, but were stimulated at this temperature by addition of 1% serum. This stimulation was 94% inhibited by IDF45. The same Ny68-infected cells could also be stimulated by transfer to 37 degrees C, the permissive temperature (in the absence of serum). The stimulation of DNA synthesis by src expression was poorly inhibited by IDF45. From our results, it appears that oncogene expression in CEF induces a loss in their sensitivity to IDF45. This would explain why transformed cells escape DDI of growth.     

CHANGES IN GLUCOSE OXIDATION DURING GROWTH OF EMBRYONIC HEART CELLS IN CULTURE

A rapid and convenient method has been utilized to investigate glucose oxidation during growth of chick embryo heart cells in tissue culture. Primary isolates of chick embryo heart cells showed exponential growth when plated at low densities and exhibited density-inhibited growth as cultures became confluent. The density-dependent growth inhibition of chick embryo heart cells is associated with a marked decrease in the specific activity of glucose oxidation to CO₂. This decrease in glucose oxidation was observed as density increased as either a function of time in culture or as related to initial plating density. The decrease in ¹⁴CO₂ production associated with density-dependent inhibition of growth is due to a marked decrease in activity of the pentose phosphate pathway.     

Insulin-like growth factor I/somatomedin C action on 2-deoxyglucose and alpha-amino isobutyrate uptake in chick embryo fibroblasts

Maximum 125I-IGF-I/Sm-C total binding to chick embryo fibroblasts was 3% at +37 degrees C and decreased to less than 1% in presence of 2.8 X 10(-9) M unlabelled IGF-I/Sm-C. Insulin did not compete with IGF-I/Sm-C for the binding to cells. Biological action of IGF-I/Sm-C was evaluated on 2-deoxyglucose and alpha-aminoisobutyrate uptake. Results are compared with those obtained with insulin. Maximal peptide effects on the two transport processes were obtained at a 0.65 X 10(-7) M concentration and for a 120 minute association time, whereas cells were markedly less sensitive to insulin and time response curves were different. These results suggest that insulin action on nutrient uptake in chick embryo fibroblasts is not mediated by the binding of the hormone to IGF-I/Sm-C receptors.     

Insulin regulates protein metabolism in mouse blastocysts

Mouse blastocysts, in vitro, endocytosed 100 μg/ml ¹²⁵I-labelled bovine serum albumin (BSA) at a rate equivalent to 192 ± 27 μl/hr/mg embryonic protein over the first 20 min. Insulin stimulated this initial uptake by 30% (P < 0.05). After this time, accumulation of ¹²⁵I-labelled BSA began to plateau as the endocytosed ¹²⁵I-labelled BSA was catabolized and ¹²⁵I was released from the cells. Insulin caused an ≈?72% (P < 0.05) increase in the amount of uncatabolized ¹²⁵I-labelled BSA remaining in insulin-treated blastocysts after 2 hr as compared to control blastocysts. Insulin partially inhibited catabolism of endocytosed ¹²⁵I-labelled BSA during the first 2 hr following transfer to nonradioactive medium. After this time, degradation ceased in both control and insulin-treated blastocysts, leaving a small, uncatabolized protein pool remaining in the embryos; however, as a result of insulin's inhibitory effects on the initial catabolic rate, the uncatabolized protein pool was 30% (P < 0.05) larger in insulin-treated blastocysts after the 4 hr chase. Insulin inhibited endogenous protein degradation in blastocysts by 37% (P < 0.05). Combined with previous studies showing a 90% increase in endogenous protein synthesis in blastocysts following short-term stimulation with insulin (Harvey and Kaye, 1988), these results suggest that insulin acts to increase the endogenous protein-reserves in the embryo. Dose-response studies indicated an EC₅₀ of 0.5 pM for insulin's stimulation of ¹²⁵I-labelled BSA accumulation, consistent with action via its own receptor. Insulin-like growth factor-1 (IGF-1) also stimulated protein accumulation at concentrations similar to those observed with insulin, suggesting that IGF-1 may act via its own receptor rather than the insulin receptor to exert its effects on endocytosis. © 1993 Wiley-Liss, Inc.     

The kinetic characteristics of the process of the contact stimulation of cell multiplication in a chick embryo cell culture

As was reported elsewhere (Gasparian, Grigorian, 1989a, 1989b), the stimulation of cell proliferation takes place in established culture of chick embryo cells after adding a suspension of living or inactivated homologous cells. In the present paper the kinetic parameters of this process, termed as the contact stimulation of cell proliferation, were studied. The dose- and time-dependence of cell response to the stimulus is described. It was shown that the addition of cells activates cell growth both in exponential and stationary cultures. DNA synthesis in resting cells is seen initiated only if their continuous interaction with the added cells is provided. The nature of signals involved in the process of contact stimulation is described.     

Alteration of insulin binding and cytoskeletal organization in cultured fibroblasts by tertiary amine local anesthetics

Tertiary amine local anesthetics cause a time- and dose-dependent, reversible increase in insulin binding sites in cultured chick embryo fibroblasts. Incubation of fibroblasts with 0.2 mM dibucaine for 3 h at 37°C results in a twofold to threefold increase in insulin binding, with an increase in average number of binding sites (K_a = 3.0 × 10⁷M^?1) from 9 × 10³ to 29 × 10³ per cell. Trypsin or ethylenegly coltetraacetic acid (EGTA) alone increases insulin binding twofold to threefold, but fails to further increase ¹²⁵I-insulin binding in cells pretreated with dibucaine. Transformation of chick embryo fibroblasts with Rous sarcoma virus causes a threefold to fivefold increase in insulin binding, which is not further increased by incubation with dibucaine. As demonstrated by transmission electron microscopy, dibucaine and trypsin also induce changes in the cytoskeleton of chick embryo fibroblasts, characterized by disorganization and disappearance of microfilament and microtubule bundles. These alterations are accompanied by gross morphologic changes, including rounding of cells and appearance of numerous ruffles and blebs on the cell surface. These observations are consistent with the hypothesis that expression of surface receptors in cultured chick embryo fibroblasts is related to the organization and disorganization of cytoskeletal structures.     

In Vitro effects of thyroxine and insulin on myoblasts from chick embryo skeletal muscle

The role of insulin and l-thyroxine (L-T₄) in stimulating myoblast proliferation and differentiation was investigated in vitro. A superphysiological concentration of insulin or a physiological concentration of L-T₄ was added to cultures of myoblasts from 11-day-old chick embryo thigh muscle, grown in serum-free DM-153 medium. While the addition of insulin resulted in an increase in the total number of cells, in the extent of fusion, and in the creatine phosphokinase (CPK) activity, myotubes changed into globular structures which tended to degenerate rapidly. On the other hand, while the addition of L-T₄ had less effect on myogenesis, myotubes retained their differentiated state longer. Furthermore, the two hormones exhibited synergistic effects. An increase in the initial cell density resulted in an increase in the amount of protein and CPK activity, irrespective of the presence or absence of the hormones. This suggests that the effect of insulin and L-T₄ on myogenesis is not a differentiation-specific effect, but rather an indirect result of cell proliferation.     

Evidence for contact stimulation of growth of homologous cells in superinoculated cultures of chick embryo cells

The secondary cultures of chick embryo cells were suspended and transferred to homologous cell cultures. Cell adhesion and proliferation were studied in these superinoculated cultures. It was shown that added cells soon adhered to the underlying cell layer which results in a prompt increase in culture density followed by the activation of DNA synthesis and cell division. Stimulation of cell proliferation involved both cell subpopulations composing the superinoculated culture: cells seeded on the built-up cell layer and cells of the layer. The contact nature of added cell mitogenic action on overlaid cell proliferation was evidenced. The cell system described can be used to investigate the adhesive properties of the cell layer apical surface, the relationship between cell growth rate and culture density, and the contact stimulation of cell proliferation.     

Insulin reduces apoptosis and increases DNA synthesis and cell size via distinct signalling pathways in Drosophila Kc cells

During development of Drosophila, cell proliferation and size are known to be regulated by insulin. Here we use Drosophila Kc cells to examine the molecular basis for the control of cell growth by insulin. Growing cells in the presence of insulin increased cell number above control levels at 16, 24, 48 and 72 h. We have demonstrated a novel anti-apoptotic effect of insulin (approximately 50%) in these cells, measured by caspase 3-like activity, which contributed to the increase in cell number. The anti-apoptotic effect was observed both in control cells and those in which apoptosis was induced by ultraviolet irradiation. An approximately 2-fold stimulation of bromodeoxyuridine incorporation demonstrated that insulin also increased Kc cell proliferation by stimulating new DNA synthesis. The ability of insulin to increase cell number, stimulate bromodeoxyuridine incorporation and reduce caspase 3-like activity was prevented by PD98059, which inhibits activation of the Drosophila extracellular signal regulated kinase (DERK) pathway, and was unaffected by wortmannin, an inhibitor of Drosophila phosphatidylinositol 3-kinase (DPI3K). Insulin also increased cell size approximately 2-fold and this was prevented by wortmannin and rapamycin, an inhibitor of Drosphilia target of rapamycin (DTOR). In summary, we show that DERK plays an important role in mediating the effect of insulin to reduce apoptosis and increase DNA synthesis whereas the DPI3K/DTOR/Dp70S6 kinase pathway mediates effects of insulin on cell size in Drosophila Kc cells.     

Early cellular responses to diverse growth stimuli independent of protein and RNA synthesis.

Serum, elevated pH, excess Zn++, 9,10 dimethyl-1,2 dibenzanthracene (DMBA) and insulin accelerate the progress of growth-inhibited chick embryo cells into the S-period of DNA synthesis. A comparative study was made of their capacity to elicit other cellular responses within two hours after their application. All the agents studied stimulated the uptake of the glucose analogue 2-deoxy-D-glucose (2-dGlc). Elevated pH elicited a more striking increase than the other agents in the uptake of the amino acid analogue alpha-amino isobutyric acid (AIB). The application of subtoxic concentrations of Zn++ or DMBA did not stimulate the uptake of uridine by cells nor its incorporation into RNA when tested at 2 hours. However, it was found that the stimulation of uridine utilization did occur but was delayed several hours. Similarly, the accelerated onset of DNA synthesis was also delayed for several hours by these agents. Insulin acted like serum in stimulating the utilization of 2-dGlc, AIB and uridine. Serum and DMBA were particularly effective in stimulating the utilization of choline. It was concluded that the utilization of 2-dGlc, uridine and thymidine are affected similarly by all the agents, but that there may be differential effects in the utilization of AIB and choline. The inhibition of RNA synthesis by actinomycin D did not prevent the relative stimulation of 2-dGlc, AIB and choline utilization by serum and pH treatment. The inhibition of protein synthesis by cycloheximide did not prevent the relative stimulation of 2-dGlc and choline utilization by serum and pH treatment. It partially blocked the increased uptake of AIB and had erratic effects on the utilization of uridine. It was concluded that neither RNA nor protein synthesis is required for some, if not all, the early responses to growth stimuli measured here. The inhibited cell appears to be a poised system which carries out a programmed array of reactions characteristic of the cell type following perturbation by a variety of unrelated agents. In vivo specificity is provided by the physiological reagents available (i.e., hormones) and their capacity to interact with different cell types.